Supplemental Online Materials
Experimental Procedures
A. Experimental materials
Cucumber seeds (Cucumis sativus cv “Marketmore 76”, Johnny’s Seeds) were sorted to remove damaged seeds, individually screened to 0.02 – 0.03 g biomass, surface disinfested with a 0.5% sodium hypochlorite Tween80 solution for 5 min, rinsed three times with sterile Nanopure® water and air dried under sterile conditions. Quartz sand was wet sieved to 0.5 - 1.0 mm diameter, oven dried and autoclaved 40 min on three consecutive days before use. Vermicomposted dairy manure (VDM) (Worm Power, Avon NY) was collected, stored at -20⁰C and thawed at room temperature for 24 h before use in all experiments. Autoclaved vermicompost was prepared by autoclaving vermicompost on three consecutive days, storing at -20⁰C and thawing for 24 h under sterile conditions before use in all experiments. Vermicompost was prepared from dewatered dairy manure solids which were mixed 7:1:1 with spoiled corn and hay silage and cured hot compost. This mixture was thermogenically composted in a forced air system for up to 2 weeks. Material was then added to continuous flow-through vermicomposting systems stocked with Eisenia fetida and Dendrobaena venata every 3-4 d in 5 cm layers. Finished vermicompost was removed from the underside of the continuous flow-through system and sieved to 10 mm 75 d after the initiation of hot composting. Before use in bioassays, 500 g of vermicompost was placed in a 0.25 mm sieve and soaked in 4 L Nanopure® water for 5 min before being allowed to drain. This additional step was performed in order to reduce soluble nutrients and prevent excessive bacterial growth in tubing used in the bioassay apparatus.
Pythium aphanidermatum (Edson) Fitzp (Pa58)(Ben-Yephet and Nelson, 1999)was cultured on clarified V8 juice agar plates at 27⁰C. To maintain virulence and prevent bacterial contamination, cucumber seeds were inoculated with Pa58 zoospores weekly, infected seeds were overlaid with KWARP (water agar with kanamycin sulfate 0.025 mg mL-1, rifampicin 0.015 µg mL-1 and penicillin G 0.015 µg mL-1) and hyphal tips that emerged 24 h later were transferred to clarified V8. For zoospore preparation, a core borer (#15, 20 mm diam) was used to remove discs from 7 d Pa58 cultures. Each disk was placed in a 70 mm petri dish with 10 mL sterile Nanopure®water for 17 h at 27⁰C. Liquid was then replaced with 10 mL sterile Nanopure® water and discs were incubated at 27⁰C for an additional 7 h. Zoospores were enumerated with an Improved Neubauer Haemocytometer and diluted with sterile Nanopure® water if necessary. Zoospore suspensions were used immediately after preparation.
B. Disease suppression bioassay
Bioassays were conducted in fritted glass Büchner funnels that held matric potential (Ψm) at a constant -3.5 kPa in a growth chamber at 27⁰C and 18 h photoperiod (Dimock growth chamber facility, Cornell University). In the apparatus, fritted glass Büchner funnels were attached to a water column held under vacuum with one end placed in an open reservoir, based on the design of Chen and Nelson(Chen and Nelson, 2008) (Supplemental Figure S1). This strict level of water control was necessary because of the exacting requirements for zoospore homing responses and maintaining consistent conditions for examination of microbial action in the spermosphere(Kliejunas and Ko, 1974; Duniway, 1976; Mandelbaum et al., 1993). Cucumber seeds (10 per funnel) were sown in 150 cm3 of one of three substrates in the funnels; sterile quartz sand (wet sieved to 0.5 – 1.0 mm diameter), sterile quartz sand amended with 40% (v:v) vermicompost and sterile quartz sand amended with 40% v:v autoclaved vermicompost. Substrates were flooded for 30 min and 50 mL zoospore suspension (1.2 x 104 zoospores mL-1) was added to inoculated funnels. Substrates were then drained and covered with ventilated Parafilm M to create a moist chamber. Seedlings were harvested 7 d after inoculation and assessed for disease symptoms as determined by shoot height, seedling health rating, seedling survival, and disease incidence. Seedling health was rated on a scale of 0-5 where 0=dead and completely rotted, 1=fallen over but not completely rotted, 2=cotelydon and stem lesions, 3=cotelydon lesions only, 4=stem lesions only, and 5=healthy. Disease incidence data (presence or absence of symptoms) were analyzed in SAS v9.3 using binary logistic regression with Bonferroni’s correction for multiple comparisons. Health ratings were analyzed in SAS v9.3 using ANOVA in the general linear model with Tukey’s correction for multiple comparisons.
C. Zoospore mass flow in bioassay apparatus
To ensure that zoospores added to the bioassay apparatus actively swim to reach seeds and are not distributed throughout the funnel by mass flow, a 5 mL suspension of either actively swimming or mechanically encysted non-motile Pa58 zoospores (8 x 104 zoospores mL-1) were added at a point source in the center of the bioassay apparatus. Cucumber seeds were sown in sand with 4 cm spacing. The viability of mechanically encysted non-motile zoospores was tested by adding 5 mL encysted Pa58 zoospores (8 x 104 zoospores mL-1) to the center of the bioassay apparatus. For this test, cucumber seeds were sown at 1 cm spacing to ensure contact with zoospores. After 24 h, seeds were transplanted to funnels containing sterile sand to prevent potential infections from secondary zoospores. At 48 hpi half the seeds were removed and plated on KWARP to score for the presence or absence of Pa58. Remaining seedlings were harvested 8 d after sowing to assess disease symptoms and seedling stand. Disease incidence (presence or absence of symptoms) was analyzed in SAS v9.3 using binary logistic regression with Bonferroni’s correction for multiple comparisons.
D. Collection of seed exudates for in vitro zoospore assays
Seeds were sown in fritted glass Büchner funnels as described above for disease suppression bioassay and allowed to germinate for 8 h in either sand or vermicompost amended sand. Seeds were then transplanted to sterile sand by moving the entire nylon mesh with embedded seeds to a new Büchner funnel for an additional 12, 18 or 24 h before being removed, see overall experimental schematic (Figure 2). The entire sand matrix of three replicate funnels was then harvested, rinsed with 1 L sterile Nanopure® water, strained through 4 layers of sterile cheesecloth, lyophilized, reconstituted in 15 mL Nanopure® water, sterile filtered to 2 µm with cellulose acetate syringe filters, lyophilized a second time and weighed. The resulting powder was stored at -80°C and reconstituted to 35 X the initial concentration in the full 150 cm3 sand matrix present in the bioassay apparatus (X = total dry seed exudate harvested/ total liquid in sand at -3.5 kPa). This reconstitution rate was determined empirically as one that would result in high numbers of zoospores responding to control exudates and is likely similar to the concentrated gradient of exudates present in the spermosphere in the disease suppression bioassay. Three separate batches of extracts were prepared and used in zoospore assays immediately following reconstitution.
Filter-sterilized seed exudates were extracted with two 500 mL portions of ethyl acetateper liter of sample. The organic layers were combined and dried over anhydrous Na2SO4 and the solvent removed in vacuo. Residue was transferred to a tared vial with ethyl acetate, dried under a N2 stream, and vacuum dried to constant weight. The water soluble layer was lyophilized. All samples were stored in -80oC prior to use in zoospore assays.
E. Quantitative PCR to Estimate Pa58 Biomass on Seeds
Quantitative PCR (qPCR) was carried out using an iQTM5 thermocycler (Bio-Rad, USA). Each 25 µL reaction contained 12.5 µL iQTM SYBR® Green Supermix (Bio-Rad, USA), 1.25 µL PaITS-F and PaITS-R (500 mM), 1 µL template and 9 µL DNase, RNase free water. P. ultimum mycelial DNA was used as a negative control and water was used as a no template control. Reaction conditions were 40 cycles of 95⁰C for 15 s and 50⁰C for 30 s. To generate a standard curve, Pa58 was cultured on V8 overlaid with sterile cellophane. Mycelia were harvested by removing the cellophane after 7 d, lyophilizing and weighing. DNA was extracted as above and quantified using a Quant-iTTM PicoGreen® dsDNA quantification kit (Invitrogen, USA) and a VersaFluorTM fluorometer (Bio-Rad, USA). DNA harvested from lyophilized mycelia was used in each qPCR plate with a range of concentrations 1 fg to 10 ng µL-1. To ensure that the presence of the cucumber seed and/or the VDM substrate did not interfere with DNA extraction or PCR amplification, additional treatments were used. Cucumber seeds were sown in sand or sand amended with 40% v:v VDM for 24 h. Seeds sown in VDM for 8 h were combined with a known amount of lyophilized Pa58 biomass and DNA was extracted and used to generate additional standard curves in order to rule out potential deleterious effects of residual VDM on DNA extraction or PCR efficiency.
Results
A. Suppressiveness of vermicompost to P. aphanidermatum-incited seedling disease
The presence of vermicomposted dairy manure (VDM) significantly reduced the incidence and severity of disease relative to the non-amended control. Seedlings inoculated with P. aphanidermatum (Pa58) zoospores in non-amended sand had 97% mortality after 7 d whereas seedlings sown in sand amended with 40% v:v VDM had significantly lower seedling mortality with a range of 11 to 20% for three different VDM batches. Non-inoculated seedling mortality (0%) could not be included in the statistical analyses as this would confound the logistic regression procedure. Seedling health rating was highest for all non-inoculated seedlings in every treatment followed by the inoculated vermicompost batches in descending order (Batch 1 > 3 > 2), and then inoculated sand with the lowest health rating (Figure 1, Table 1).
B. Zoospore mass flow in bioassay apparatus
Mechanically encysted zoospores showed a limited ability to cause infection when added to substrates 2 cm away from germinating seeds (Figure S1), which reduces the likelihood that zoospores arrived at the seed surface through mass flow instead of active swimming to cues from seeds. A significantly greater number of seedlings survived when seeds were sown 2 cm from the encysted zoospore inoculation point (73% survival at 9 days post inoculation [dpi]) than those sown 2 cm from the swimming zoospore inoculation point (4% survival at 9 dpi, p<0.0001) and this pattern was reflected in the proportion of seeds colonized with P. aphanidermatum 48 hours post inoculation (hpi). Mechanically encysted zoospores maintained their viability, causing high seedling mortality when inoculated directly onto germinating seeds (7% survival).
Supplementary Figures
Figure S1.Bioassay apparatus; A) Arrows indicate where water column is exposed to air, height of water column = 35 cm which gives -3.5 kPa matric potential in the fritted glass Büchner funnel, B) Sand and seeds added to the funnel, funnel being passively flooded while Erlenmeyer flask is on the upper shelf, C) Nylon membrane with surface disinfested cucumber seeds sown in a 4 cm diameter circle, red X indicates location of zoospore inoculation once the matrix has been equilibrated at -3.5 kPa matric potential.
Figure S2.Individual compounds detected at a significantly lower relative abundance in VDM microbially modified seed exudate (MME) compared to control seed exudate (CE). Six biological replicates per treatment were considered as indicated by column headings. Relative abundances derived fromgas and liquid chromatography combined with mass spectrometry (GC/LC-MS). Scaled imputed data derived from raw integrated peak ion counts for individual compounds were natural log transformed and subjected to a Welch’s two way t-test to calculate p-values for treatment differences. Heat map colors as follows; blue = lower relative abundance, black = no change, yellow = higher relative abundance.
Supplemental References
Ben-Yephet, Y., and Nelson, E.B. (1999) Differential suppression of damping-off caused by Pythium aphanidermatum, P. irregulare, and P. myriotylum in composts at different temperatures. Plant Disease 83: 356-360.
Chen, M.-H., and Nelson, E.B. (2008) Seed-colonizing microbes from municipal biosolids compost suppress Pythium ultimum damping-off on different plant species. Phytopathology 98: 1012-1018.
Duniway, J.M. (1976) Movement of zoospores of Phytophthora cryptogea in soils of various textures and matric potentials Phytopathology 66: 877-882.
Kliejunas, J.T., and Ko, W.H. (1974) Effect of motility of Phyophthora palmovira zoospores on disease severity of papaya seedlings and substrate colonoization in soil Phytopathology 64: 426-428.
Mandelbaum, R., Hadar, Y., and Chen, Y. (1993) Simple apparatus to study microbial activity in organic substrates under constant water potential. Soil Biol Biochem 25: 397-399.
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